Researchers demonstrate ‘no-ink’ color printing with nanomaterials

June 11, 2015

Missouri S&T researchers have developed a method to accurately print high-resolution images on nanoscale materials. To demonstrate the process, they printed the Missouri S&T athletic logo (left) at the nanoscale level (right; scale bar: 10 micrometers) (credit: Missouri University of Science and Technology)

The researchers describe their printing method in an open-access article in the latest issue of Nature Publishing Group’s Scientific Reports and illustrate their technique by reproducing the Missouri S&T athletic logo on a nanometer-scale surface.

The method involves the use of thin sandwiches of nanometer-scale metal-dielectric materials known as metamaterials that interact with light in ways not seen in nature.

Experimenting with the interplay of white light on multi-layer plasmonic interfaces, the researchers developed what they call “a simple but efficient structural color printing platform” that holds promise for future applications, including nanoscale visual arts, security marking, and information storage.

The printing surface consists of a sandwich-like structure made up of two thin films of silver separated by a “spacer” film of silica. The top layer of silver film is 25 nanometers thick and is punctured with tiny holes created by a microfabrication process known as focused ion beam milling. The bottom layer of silver is four times thicker than the top layer but still minuscule at 100 nanometers. Between the top and bottom films lies a 45-nanometer silica dielectric spacer.

The researchers created a scaled-down template of the athletic logo and drilled out tiny perforations on the top layer of the metamaterial structure. Under a scanning electron microscope, the template looks like a needlepoint pattern of the logo. The researchers then beamed light through the holes to create the logo, using no ink — only the interaction of the materials and light.

By adjusting the hole size of the top layer, light at the desired frequency was beamed into the material with perfect absorption. This allowed researchers to create different colors in the reflected light and thereby accurately reproduce the S&T athletic logo with nanoscale color palettes. The researchers further adjusted the holes to alter the logo’s official green and gold color scheme to introduce four new colors (an orange ampersand, magenta “S” and “T,” cyan pickaxe symbol and navy blue “Missouri”).

“To reproduce a colorful artwork with our nanoscale color palettes, we replaced different areas in the original image with different nanostructures with specified hole sizes to represent various visible colors,” says Dr. Xiaodong Yang, an assistant professor at Missouri S&T, who leads the Nanoscale Optics Laboratory in the university’s mechanical and aerospace engineering department. “We chose the athletic logo to fill that need.”

“Unlike the printing process of an inkjet or laserjet printer, where mixed color pigments are used, there is no color ink used in our structural printing process – only different hole sizes on a thin metallic layer,” says Dr. Jie Gao, an assistant professor of mechanical and aerospace engineering at Missouri S&T and a co-author of the paper.

In their paper, the authors note that the process resulted in “pure colors with high brightness” with little need for protective coatings. The researchers believe the process could lead to “high-performance, pigment-free color printing and relevant applications such as security marking and information storage.”

Other co-authors of the Scientific Reports paper are Dr. Fei Cheng, a researcher at Missouri S&T’s Nanoscale Optics Laboratory, and Dr. Ting S. Luk of the Center for Integrated Nanotechnologies at Sandia National Laboratories in Albuquerque, New Mexico.

Abstract of Structural color printing based on plasmonic metasurfaces of perfect light absorption

Subwavelength structural color filtering and printing technologies employing plasmonic nanostructures have recently been recognized as an important and beneficial complement to the traditional colorant-based pigmentation. However, the color saturation, brightness and incident angle tolerance of structural color printing need to be improved to meet the application requirement. Here we demonstrate a structural color printing method based on plasmonic metasurfaces of perfect light absorption to improve color performances such as saturation and brightness. Thin-layer perfect absorbers with periodic hole arrays are designed at visible frequencies and the absorption peaks are tuned by simply adjusting the hole size and periodicity. Near perfect light absorption with high quality factors are obtained to realize high-resolution, angle-insensitive plasmonic color printing with high color saturation and brightness. Moreover, the fabricated metasurfaces can be protected with a protective coating for ambient use without degrading performances. The demonstrated structural color printing platform offers great potential for applications ranging from security marking to information storage.